Conversion of Wood-Based Hemicellulose Prehydrolysate into

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Conversion of Wood Based Hemicellulose Prehydrolysate into Succinic acid using a heterogeneous acid catalyst in a biphasic system Sai Swaroop Dalli, Tewodros Jemberu Tilaye, and Sudip Kumar Rakshit Ind. Eng. Chem. Res., Just Accepted Manuscript • DOI: 10.1021/acs.iecr.7b01708 • Publication Date (Web): 05 Sep 2017 Downloaded from http://pubs.acs.org on September 6, 2017

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Conversion of Wood Based Hemicellulose Prehydrolysate into Succinic acid using a heterogeneous acid catalyst in a biphasic system Sai Swaroop Dalliϯ, Tewodros Jemberu Tilaye± and Sudip K. Rakshitϯ* Ϯ

Department of Chemistry and Materials Science, Lakehead University, 955 Oliver Road, Thunder Bay, ON, Canada P7B5E1

±

Department of Bioprocess Engineering, Wageningen University, 6708 PB Wageningen, Gelderland, The Netherlands.

Graphical Abstract

Abstract A novel approach for the conversion of biomass based hemicellulose prehydrolysate to high value succinic acid has been investigated using a heterogeneous acid catalyst, Amberlyst 15 and hydrogen peroxide in a biphasic system. A vital intermediate in this process, furfural, was oxidized in a biphasic system to produce succinic acid. Production of furfural in good yields is a limiting step in such processes for a number of reasons. Among the organic solvents evaluated, toluene was found to be an ideal solvent for furfural extraction and facilitated the conversion of furfural to succinic acid. Simultaneous extraction of furfural into the organic solvent as it is produced, increased the overall yield. It was observed that the developed method resulted in a succinic acid yield of 52.34% from the furfural obtained from hemicellulose prehydrolysate. It was found that 50 mg of Amberlyst 15 per mmole of furfural resulted in 100% FA conversion in less time. Keywords Renewable resource, hemicellulose, furfural, succinic acid, heterogeneous catalyst, biphasic systems. 1

Introduction

Succinic acid (SA) was identified by the Department of Energy, US,1 as a platform chemical that will have a very high market in the near future. It plays a major role as a building block in 1 Corresponding author: Prof. Sudip K. Rakshit. Email: [email protected]; Tel. 807 343 8415 ACS Paragon Plus Environment

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synthesis of several polymers.2-3 It has several applications in food, cosmetics, pharmaceuticals, biopolymers, polyesters, polyurethane, plasticizers and fine chemical industries.4-5 In 2007, a market of 15 billion USD was projected for the chemicals which can be synthesized from succinic acid.6 However, it has failed to reach such growth in production due to the high costs involved in its production. In 2015, the global production was 58.5 kilotons7 and it is projected to reach 251.3 kilotons worth 701.0 million USD by 2022.7 One of the conventional methods for the production of succinic acid is the chemical conversion of maleic acid using heterogeneous metal catalyst like Pd/C. 8 Though the yields of SA are high, concerns on the use of petroleum based resources and expensive catalysts motivate researchers to look for alternative raw materials. Renewable substrates like agricultural and forest based residues have high potential for the production of succinic acid. However, its production from renewable lignocellulosic raw material is not carried out in industrial level. Statistical studies indicate that the US, for example, produces approximately 1 billion tons of inedible biomass from forests and agricultural lands.9 Therefore, several researchers are exploring alternate routes for the production of SA from low value substrates to reduce the overall production costs involved. Microbial fermentation of various substrates like hexose and glycerol using Actinobacillus succinogenes,10 Mannheimia succiniciproducens11 and Anaerobiospirillum succiniciproducens12 have been reported.13 For example, in Canada, BioAmber is one of the recently established industries for the production of biosuccinic acid. Other companies such as Riverdia, BASF – Corbion, Myriant and PTT MCC Biochem located at different parts of the world are also showing great interest in production of bio-succinic acid. However, its production is from corn starch,

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not from inedible biomass like cellulose/ hemicellulose. The disadvantages of

fermentative production of succinic acid include the duration of process (38 – 84 hours)13 and the laborious and expensive downstream processes. Succinic acid produced from fermentation was estimated to cost 2.2 USD per kilogram with a production level of 5000 tons per year.15 However, it has been projected that the price would drop to 0.55 USD if the production level increases to 75000 tons per year.15 Alternative routes reported in literature for the production of succinic acid include the oxidation of 1,4-butanediol with nitric acid,16 carbonylation of ethylene glycol, ethylene, acetylene,

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dioxane,3 hydrogenation of fumaric acid in presence of Ru catalyst,17 and condensation of acetonitrile to produce butanedinitrile which can be subsequently hydrolyzed to succinic acid.1819

Recent studies have shown that succinic acid can also be produced from furfural using a

chemical conversion pathway without a metal catalyst,20 for example, oxidation of levulinic acid using hydrogen peroxide.21 Choudhary et al. (2013) have stated that carboxylic acids like succinic acid can be synthesized from furan derivatives through the oxidative process using hydrogen peroxide in the presence of acid catalyst.4 They have reported that Amberlyst-15 is an efficient replacement for the homogeneous acid catalyst in the oxidation of furans in water. Amberlyst-15 is a sulfonated polystyrene based ion-exchange resin with 4.7 mmol/g acidity.22 It has a similar effect as sulfuric acid (H2SO4) in the synthesis of carboxylic acids from furan derivatives.23 The heterogeneous catalyst, Amberlyst-15 has an advantage because it exists in solid phase and can be recycled easily for the oxidation reactions of furan derivatives like furfural, hydroxymethyl furfural, furoic acid etc. These furan derivatives are usually obtained from hexose and pentose sugars of edible and inedible crops. However, limited information is available in literature for the use of renewable resources such as hemicellulose prehydrolysate from agriculture or forest residue for the production of carboxylic acids such as succinic acid. Xylose in hemicellulose can be converted to furfural which can then be converted to succinic acid. The major problem associated with the conversion of xylose to succinic acid is that furfural, an intermediate in this process, polymerizes and undergoes side reactions to form undesired products. It is important to avoid these side reactions during such conversions without loss in the substrate. The aim of this study was to avoid the side reactions and enhance the conversion of hemicellulose to succinic acid in good yields. Conversion of hemicellulose prehydrolysate containing xylose to succinic acid was demonstrated in this paper with the use of a biphasic system. The recyclability of the heterogeneous catalyst was also studied. 2 2.1

Material and Methods Substrate and standards

Hemicellulose prehydrolysate was obtained from GreenField Specialty Alcohols Inc., Canada. It was produced from poplar wood chips using their proprietary pretreatment process.24 Analytical

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grade furfural and succinic acid were purchased from Sigma Aldrich, whereas xylose, hydrogen peroxide, sulfuric acid and organic solvents namely toluene, ethylacetate, chloroform were purchased from Fisher Scientific. All the chemicals and solvents were used without further purification. 2.2

Experimental procedure

The aqueous hemicellulose prehydrolysate (50 mL) was added to toluene (125 mL) in a round bottomed flask at room temperature resulting in a two-phase system. Sulfuric acid (2% w/w) was carefully added while the biphasic system was stirred. The round bottomed flask was attached to a reflux condenser and placed in an oil bath. The temperature of the oil bath was increased to 100OC and the mixture was maintained at the temperature under stirring until all the xylose in prehydrolysate is converted into furfural. The system was then cooled down to room temperature to separate the aqueous hydrolysate from toluene phase. The aqueous layer containing unconverted xylose was hydrolysed again until all the xylose present was converted. The toluene solution was used in further step for the synthesis of succinic acid. A minimal amount of deionized water (10% v/v), Amberlyst 15 (50 mg) and hydrogen peroxide (4 mmole/ mmole of furfural) were added to the toluene phase obtained in the previous step. The temperature was then increased to 80 oC and maintained for 24 h. The whole reaction process was pictorially represented in the Figure 1. After the reaction, the aqueous layer and the catalyst, Amberlyst 15 were separated from the organic phase. The separated Amberlyst was washed and reused in subsequent batch of experiments. The toluene phase was analyzed for the residual furfural using a GC-FID. Once most of the furfural in toluene was converted, it was distilled to obtain relatively pure toluene and reused for subsequent batches of experiments. The aqueous layer was analyzed for the unreacted H2O2 and succinic acid concentration. The aqueous layer was then concentrated in a rotary evaporator and filtered to remove undissolved particles. The resultant solution was cooled down to 4OC to crystallize out the succinic acid. The crystallized product was analyzed using an HPLC to confirm the purity of succinic acid.

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Figure 1. Schematic representation of simultaneous production, separation and oxidation of furfural to produce succinic acid. 2.3

Determination of unreacted H2O2

The resultant aqueous solution of succinic acid was analyzed for the amount of unused hydrogen peroxide present in it. The analysis was done using a conventional method of titration against a standardized 0.3N potassium permanganate solution in presence of sulfuric acid.25 The titration of the resultant aqueous solution was done until the solution turns pink which is considered to be the end point of the titration. 3 3.1

Analytical techniques HPLC

The composition of hemicellulose prehydrolysate, aqueous phases separated and the final product (succinic acid) were analyzed using an HPLC (Agilent Technologies 1260 Infinity) with Bio-Rad Aminex HPX-87H ion exclusion column (300mm x 7.8mm) and a Refractive Index Detector (RID). The mobile phase used in this method was 5 mM H2SO4 with a flow rate of 0.5 mL/min at 50 oC. The instrument was calibrated with standards of varying concentration and the response factor (RF) obtained for the standards was used to calculate the concentrations of the products formed. 3.2

GC-FID

Furfural in toluene was analyzed using a Thermo-scientific GC (Trace 1300 series) with Flame Ionization Detector (FID) and a capillary column (Trace Gold -TG-WAXMS A) (30 m length, 0.25 mm internal diameter, and 0.25 µm film thickness of cross linked polyethylene glycol). A new method was developed to analyze furfural with low retention time. A ramped flow rate of the carrier gas was used with initial flow rate of 5 mL/min for 0.74 min and subsequently

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reduced and maintained at 4 mL/min until the end of the run. The temperatures of the oven and the detector were maintained at 200oC and the inlet temperature was maintained at 250oC. Split mode (split flow: 200; split ratio: 40) injection was used in the analysis. Initially, the GC was calibrated with standards at different concentrations. Response factor (RF) of the standard furfural was obtained by the equation: [Peak area] = RF[standard concentration]. The obtained RF was used to determine the unknown concentration of furfural in the samples obtained during the reaction. 4 4.1

Results and Discussion Characterization of the hemicellulose prehydrolysate substrate (PHL)

GreenField Specialty Alcohols Inc. provided the poplar hemicellulose prehydrolysate liquor (PHL) which was obtained from a novel two stage steam percolation pretreatment process.24 The concentrated PHL supplied was stored in a freezer at -20 oC for future use. The composition of the PHL was analysed using HPLC-RID to determine sugars and other components quantitatively (Table 1). The PHL mostly contained oligosaccharides and polysaccharides along with some monomeric sugars and furan compounds. These furan compounds could be formed due to severe conditions during the pretreatment process.26 Table 1. Composition of the hemicellulose prehydrolysate used in this study. Component

4.2

Concentration (g/L)

Xylo-oligosaccharides

52.30

Xylose

31.97

Glucose

2.11

Arabinose

3.18

Acetic acid

2.37

Hydroxy methylfurfural

1.02

Furfural

0.35

Hemicellulose conversion into succinic acid

conventionally, succinic acid is produced at large scale using either metal catalyzed conversion of maleic acid or fermentation of glucose. However, xylose obtained from the pretreatment of prehydrolysate also has high potential to be converted into succinic acid via furfural. Few reports

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in literature discuss the conversion of furfural to succinic acid.4, 20, 27 Succinic acid production from hemicellulose is challenging because of several constraints associated with acid hydrolysis of hemicellulose, the conversion of the intermediate, furfural to byproducts etc. In this study, we first addressed the limitations of furfural yield due to the formation of byproducts like humins. Optimization of acid hydrolysis of hemicellulose prehydrolysate was done to determine the best conditions for high yields of furfural. We then compared a few organic solvents to determine an ideal solvent to separate furfural from the hydrolysate. By using these optimal conditions, we demonstrated the use of biphasic system for the production and simultaneous separation of furfural from the hemicellulose prehydrolysate. Finally, the conversion of furfural into succinic acid was also done using a biphasic system. The method of conversion was adopted from Choudhary et al. (2013).4 However, our report shows the use of a biphasic system for the production of succinic acid from hemicellulose derived furfural using heterogeneous acid catalyst. 4.2.1

Optimization of acid hydrolysis of PHL

In the production of succinic acid from hemicellulose prehydrolysate, furfural plays an important role as the precursor of succinic acid. Hence, it is essential to produce furfural in good quantities which is subsequently converted to succinic acid. The polymeric form of xylose, xylan in hemicellulose gets hydrolyzed in the presence of acid to produce xylose which in turn dehydrates to form furfural in the same conditions. The reactions occur in the prehydrolysate during acid hydrolysis is shown in the scheme 1. XYLAN

+

ACID

XYLOSE

XYLOSE

-

3 x WATER

FURFURAL

SUGARS/

FURFURAL +

FURFURAL

HUMINS + RESINS

Scheme 1. Set of reactions take place during acid hydrolysis of prehydrolysate. Various acid catalysts have been studied and discussed in literature for the hydrolysis of biomass.28-29 These reports indicate that sulfuric acid facilitates efficient hydrolysis. Therefore, it has been chosen to produce furfural from the hemicellulose prehydrolysate. Several processes and methodologies of acid hydrolysis have been invented and developed in the past and well discussed in literature.30 Due to environmental concerns, it is always recommended to use dilute

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sulfuric acid at low dilutions. According to British Pharmacopoeia, any concentration below 10% (w/v) of sulfuric acid is considered as dilute.31 we tried different acid concentrations under atmospheric and high pressure conditions in an autoclave at 121 oC and 15 psi pressure (Table 2). Low sulfuric acid concentrations as well as high acid concentrations yielded less furfural. Therefore, a range of acid concentrations were studied to determine optimum concentrations. Table 2. The concentrations of xylose, furfural and humins obtained in the acid hydrolysis of prehydrolysate after 4 h using different acid concentrations. 1% acid hydrolysis

1.5% acid hydrolysis

2% acid hydrolysis

2.5% acid hydrolysis

10% acid hydrolysis

10% acid hydrolysis in autoclave

84

80

96

79

76

75

Furfural (g/L)

4.16

5.8

6.0

6.24

1.28

5.91

Humins (g/L)

2.7

4.8

6.6

7.8

33.3

33.2

Xylose (g/L)

The hydrolysis of prehydrolysates using 1% sulfuric acid resulted in high xylose quantities but relatively low furfural. The activity of acid was not sufficient to hydrolyze the PHL and convert the xylose at the same time to produce furfural. Increasing the acid concentration resulted in higher furfural concentrations along with the increase in humins. However, in order to compare the effect of acidic strength, xylose to furfural and furfural to humins ratio were considered. In both the cases, 2% sulfuric acid has shown better results than other concentrations. The high xylose to furfural ratio is advantageous because the xylose produced in the hydrolysis can be hydrolyzed separately to produce furfural subsequently. On the other hand, in the case of high furfural to humin ratio, it is evident that low amount of furfural was converted to humins during the hydrolysis. The hydrolysis using 10% acid yielded very low amounts (1.28 g/L) of furfural and high amount (33.3 g/L) of humins. The yield of furfural of 10% acid hydrolysis was much lower than the hydrolyses using diluted concentrations. Therefore, it is evident that most of the furfural produced was converted to humins. However, some reports suggest that production of furfural is much effective under pressure.32 Therefore, we used an autoclave for the acid hydrolysis of prehydrolysate at 15 psi pressure and 121oC temperature with 10% sulfuric acid. We have observed that furfural concentration increased to 5.91 g/L with 33 g/L of humins compared to the experiments at atmospheric pressure. Even with 2% sulfuric acid, the humin formation was

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found to be relatively high. Though the acid hydrolysis under high pressure increases the yields of furfural, it also induces humin formation, substantially. This results in substantial furfural loss. Therefore, by performing the acid hydrolysis at atmospheric pressure, the polymerization of furfural can be slowed down and it is possible to obtain relatively higher levels of furfural. For the subsequent experiments, the acid concentration was lowered to 2% and hydrolysed the prehydrolysate under reflux. Under atmospheric pressure conditions, it resulted in lower amounts of humins (6.6 g/L) but high amounts of furfural (6 g/L). Therefore, it is evident that by decreasing the acid concentration, the furfural polymerization was suppressed. Due to the slow process of the side reaction, furfural was accumulated and resulted in good yields. These results were observed from the acid hydrolysis reactions which were carried out for 4 h. The xylose (96 g/L) obtained in the hydrolysis can be treated with acid repeatedly to convert it completely to furfural. However, continuous acid treatment is not recommended because after 5 - 6 h with this acid concentration, furfural was found to decrease due to the polymerization with xylose. Therefore, separating furfural from the aqueous solution of xylose after 4 h of acid hydrolysis is recommended to avoid polymerization reaction of furfural. Subsequently, the separated xylose can be hydrolysed again to produce more furfural. 4.2.2

Separation of furfural from the hydrolysed prehydrolysate (hydrolysate)

As described earlier, furfural is formed by the loss of 3 water molecules from xylose in the presence of acids. During the hydrolysis, a polymerization reaction result in loss of furfural by converting into unwanted byproducts. One way to inhibit such reactions is to separate furfural from the aqueous media intermittently. Steam distillation is a common and widely used technique in industries to separate furfural from an aqueous phase. However, separation by such method is challenging as an azeotropic mixture is formed with 35% of furfural and 65% of water by weight in solution at 370 K under atmospheric pressure.33 Therefore, it is difficult to separate all the furfural from the aqueous phase in this method. Other novel techniques are being explored to separate furfural from aqueous phase without any loss. Recently, Song et al (2015) reported a gas stripping assisted vapour permeation (GSVP) method and studied its energy efficiency.34 Adsorption on polymeric resins,35 pervaporation using hydroxy-terminated butadiene polyurethane membranes36 and a patented technology using

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organic acids37 are some of the recent developments in furfural separation. However, they are not feasible at large scale. Extraction of organic compounds, especially furan based molecules, using an immiscible solvent is commonly performed in these types of processes. Hence, we chose to use an immiscible organic solvent having high furfural solubility that is capable of extracting furfural from aqueous phase. One common way is to extract furfural after the reaction is completed and another is to use the organic solvent in the reaction media which forms biphasic system, to separate the product simultaneously as it is formed. Thus, biphasic system provides an advantage of simultaneous separation of furfural during its formation preventing side reactions like polymerization resulting unwanted products like humins.38 We have studied this method by determining a suitable solvent for furfural extraction. Several non-polar solvents were evaluated for their solubility of furfural and extractability from water. Simulation studies were also conducted using Aspen Plus software to determine the mutual solubility of organic phase, aqueous phase and furfural. 4.2.2.1 Solvent determination to extract furfural A good organic solvent can substantially enhance the extraction of furfural from the aqueous phase without interfering in the reaction. For this purpose, three solvents, chloroform, ethylacetate and toluene were evaluated for the solubility and extractability of furfural from aqueous phase (Figure 2). However, the extractability differs in each case. Three sets of aqueous furfural solutions were prepared with amounts ranging from 10 to 100 mg in water (1 mL). However, from the furfural solubility experiments, the maximum solubility of furfural in water was found to be 72 – 75 mg/mL. The vials with more than 7.5% of furfural resulted in two phases with the excess undissolved furfural. The saturated aqueous solution with dissolved furfural was taken to examine the extractability of organic solvents. The organic solvents (1 mL) under study were added to the aqueous furfural solution. The final concentration of furfural in organic solvent after extraction was analyzed using a GC-FID. Figure 2 shows the extractability (%) of the organic solvent, calculated from the concentrations of furfural in organic solvents obtained from GC results. From the Figure 2 it is evident that toluene extracted 80 – 85 % of furfural from aqueous phase at all concentrations. The extractability of the solvents was found to be in the order of toluene > Chloroform >

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Ethylacetate. However, 100% extraction of furfural was not observed in either case because of the mutual solubility of the solvents (water and organic solvent) present in the system resulting in a two-phase ternary system. From the graph (Figure 2), it is evident that toluene extractability was almost constant with various furfural concentrations. However, other solvents seem to be losing their extractability. This can be attributed to the fact that with the change in concentrations of three components (organic solvent, water, furfural), at equilibrium, some of the organic solvent was lost to the aqueous phase, predominantly and resulted in lower furfural concentration in the extractant organic phase. 100 90 80

Extractability %

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70 60 50 40 30

Toluene

20

Ethyl acetate

10

Chloroform

0 0

20

40

60

80

Initial furfural concentration in aqueous phase (mg/mL)

Figure 2. Graphical representation of extractability of the organic solvents to extract from aqueous phase. The organic/aqueous ratio is 1:1. The mutual solubility of the organic solvent and water was evaluated by plotting ternary diagrams using Aspen Plus software (version 8.4). Ethylacetate and toluene were found to solubilize furfural in high quantities. Therefore, they have been evaluated for their mutual solubility with water and furfural. Each ternary diagram (Figure 3 and 4) represents the mutual solubility of the aqueous, organic and furfural in the system. In both the ternary diagrams, the regions outside the envelop are single phase regions while the parts inside the envelop result in two phases with compositions at the end of the tie lines. The equilibrium solubility curves which form the envelop are shown in blue color and separates the two-phase regions from the singlephase regions. As examples. three tie lines which are connecting the two equilibrium solubility curves are shown in black, red, green and magenta colors. The vertices of the triangle represent

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pure components. The sides of triangle connecting any of two vertices represent mixture of two components. In the ternary diagrams, the left side of the triangle represents mixture of organic solvent and furfural in a single-phase region and illustrates organic layer and furfural are completely miscible in each other. The base of the triangle represents the miscibility of water and organic solvent. In Figure 3a, it is clearly shown that water solubility in toluene phase is very low (~1%) whereas the solubility of toluene in water is also negligible (zoomed in Figure 3b). However, in Figure 4a, the solubility of water in ethyl acetate was found to be much higher (~22.5%) whereas ethylacetate was also slightly soluble in water which is relatively higher when compared to toluene (zoomed Figure 4b).

a)

b)

Figure 3. a) Ternary diagram of liquid-liquid phase of toluene/water/furfural system simulation. b) Zoomed view of the solubility of toluene in water.

a)

b)

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Figure 4. a) Ternary Liquid-Liquid phase diagram of water/furfural/ethylacetate system. b) Zoomed view of the solubility of ethyl acetate in water. From these data, it is found that water is less soluble in toluene than in ethyl acetate. Therefore, the use of toluene as an organic solvent was found to be the best for extraction of furfural from the aqueous phase and further used in this study. 4.2.3

Succinic acid synthesis using biphasic system

From the above study, the optimum acid concentration (2% w/w) and toluene were used. The biphasic system formed by toluene and aqueous prehydrolysate helps in simultaneous furfural production and separation (Figure 1). Subsequently, the separated furfural was converted to succinic acid in the toluene phase itself. The two stages, hemicellulose to furfural conversion and furfural to succinic acid conversion are discussed in the following sections. 4.2.3.1 Hemicellulose to furfural in a biphasic system Xylose in aqueous prehydrolysate is converted into furfural with the help of an acid catalyst, sulfuric acid. In situ, sulfuric acid reacts with toluene used in the biphasic system and is converted to tosylic acid (Scheme 2) which was evident from the formation of a thick slurry immediately after addition of sulfuric acid to the biphasic system. This is in par with and reinforced by the work reported by Koeberg-Telder et al (1971) on the sulfonation of toluene at 25 oC.39 According to them, toluene is converted to mono- or di-sulfonic acid when reacted with concentrated sulfuric acid for 1 – 30 seconds.39 However, in our case, the hydrolysis was not affected because tosylic acid itself acts as a strong organic acid which is capable of carrying out the acid hydrolysis. Moreover, it was observed that when the reaction medium is heated to the required temperature, tosylic acid reverts to toluene and sulfuric acid in presence of water and the biphasic system is reformed after 40 – 60 minutes of reaction. This can be attributed to the fact that sulfonation of aromatic compounds is reversible upon heating in presence of aqueous solutions.40 Therefore, hydrolysis of hemicellulosic xylan polymer is facilitated in the biphasic system along with simultaneous conversion of xylose to furfural in aqueous layer. Subsequently, furfural produced in the aqueous layer is rapidly transferred to the toluene layer. This was monitored by analyzing the reaction sample in GC-FID.

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HO

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O S O

H2SO4 heat, aq. dilute H2SO4

Toluene

Tosylic acid

Scheme 2. Reversible reaction of sulfonation of toluene to tosylic acid in presence of acid. 4.2.3.2 Oxidation of furfural to succinic acid Furfural obtained from the previous step was oxidized to succinic acid using hydrogen peroxide in presence of Amberlyst 15. Choudhary et al. (2013) have studied the effect of various concentrations of hydrogen peroxide on the oxidation of furan derivatives.20 In their study, the mole ratio of hydrogen peroxide to furfural required for high yields of carboxylic acids was reported to be 4:1. Higher or lower concentrations of hydrogen peroxide results low yields of succinic acid. Therefore, in our study, we used the same ratio to obtain high yields of succinic acid. An acid catalyst must be used with hydrogen peroxide to produce succinic acid. Hydrogen peroxide alone oxidizes the furfural present in aqueous phase and produces furoic acid. But, in presence of acid catalyst, hydrogen peroxide selectively yields succinic acid from furfural.4 Sulfonic acid functional group on Amberlyst 15 is mainly responsible for succinic acid selectivity during the oxidation of furfural. Studies on the effect of various homogeneous acid catalysts like p-tosylic acid, hydrochloric acid, sulfuric acid, and heterogeneous acid catalysts like Amberlyst 15, Nafion NR50, Nafion SAC-13, γ- Al2O3, Nb2O5, ZrO2 has been reported elsewhere.20 Based on their report, Amberlyst 15 was chosen for our study as it has shown good catalytic activity and can be reused. Furfural in toluene phase was directly subjected to oxidation in presence of hydrogen peroxide and Amberlyst 15. However, this process takes place in the aqueous phase as hydrogen peroxide is miscible in water and immiscible in toluene. Therefore, addition of water to the toluene phase with furfural is necessary to facilitate the oxidation of furfural in presence of acid catalyst. A slight amount of water (10% V/V) is enough to solubilize succinic acid even the yield reaches 100%. According to the Institute for Occupational Safety and Health of the German Social

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Accident Insurance database, the maximum solubility of succinic acid in water is 58 mg/mL at room temperature.41 Therefore, we used 10 mL of water so that succinic acid is not saturated in the aqueous phase. Though furfural selectively dissolves in toluene, it is also dissolved partially in water present in the system. Therefore, the partial amount of furfural dissolved in aqueous phase of the biphasic system gets oxidized to succinic acid. Due to the imbalance of furfural equilibrium in two phases during the reaction, furfural tends to transfer into the aqueous phase continuously. Simultaneously, hydrogen peroxide in presence of acid catalyst in aqueous phase oxidizes the transferred furfural. The volumetric ratio of aqueous phase to toluene phase chosen for this reaction was ideal as total furfural (>99%) in toluene found to be transferred and converted. It was confirmed with GC analysis of the organic layer. The reaction of furfural oxidation to succinic acid was monitored and few samples were taken during the reaction. Succinic acid is highly polar and insoluble in toluene. Therefore, the aqueous phase was analyzed for succinic acid content using HPLC whereas the toluene phase was analyzed using GC-FID for furfural content. After the reaction, unused hydrogen peroxide content was also determined by the method described in earlier sections. It was found that almost all the hydrogen peroxide content was consumed by the end of the reaction. The average final yield of succinic acid from furfural was found to be 52.34% in 24 h. The overall reaction was shown in Scheme 3 and a schematic representation of the production process is given in Fig. 5. It was observed that in the biphasic system, the reaction was found to be faster and achieved good yields in less time. In this case, toluene acts as a reservoir for furfural and continuously supplies furfural to the aqueous phase where the oxidation takes place. Therefore, the biphasic system with toluene found to be beneficial for production and synthesis of succinic acid from hemicellulose prehydrolysate. OH O OH HO

OH

Xylose (in hemicellulose)

H2SO4

O O

O

Amberlyst 15, H2O2

-3H2O

Furfural (75%)

HO

OH

O Succinic acid (52%)

Scheme 3. Overall reaction in the production of succinic acid from hemicellulose

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Figure 5. Flow diagram of the proposed process of succinic acid production from hemicellulose prehydrolysate using biphasic system 4.2.3.3 Effect of the acid catalyst loading and its recyclability The effect of the amount of Amberlyst 15 in the reaction system was determined to study the variation in the yield of succinic acid and furfural conversion. A range of Amberlyst 15 catalyst amount (10 – 50 mg/ mmol furfural) were used to determine their effect on succinic acid synthesis. It was observed that in the first few hours of reaction, the furfural was converted into few intermediates which were subsequently succinic acid. From the Fig. 6, it is evident that 50 mg of Amberlyst 15 per each mmol of furfural was converting 100% of furfural within 4 h of reaction time. It shows that higher the catalyst loading, faster the conversion of furfural. Lower amounts of Amberlyst 15 found to convert furfural much later than 50 mg of catalyst. Hence, 50 mg of Amberlyst was used to carry out the reaction to synthesize succinic acid from furfural in the biphasic system.

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Furfural converted (%)

100 80 60 40 20 0 10

20

30

40

50

Amberlyst 15 loading (mg) per 1 mmol of furfural

Figure 6. Graphical representation of effect of catalyst loading in the oxidation of furfural at 4 hours of reaction time. Amberlyst-15 has the benefits of ease of use, separation and recyclability for subsequent batches of experiments. In this work, high solubility of final product in the aqueous phase had facilitated the recovery of the catalyst easily and reuse for 3 times (Fig. 7). The succinic acid yield found to be increased for 2 cycles and reduced subsequently. Although the reaction media was stirred at low speed (100 rpm), the beads of the heterogeneous catalyst were found to break down and could not be used beyond the third recycle. The succinic acid yields obtained in each batch of experiment using the recycled catalyst are compared in Fig. 7. 70 60

Succinic acid yield %

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50 40 30 20 10 0 1

2

3

Experiment cycle

4

Figure 7. Comparison of overall succinic acid yields obtained from the oxidative conversion of hemicellulose derived furfural using recycled Amberlyst 15 in a biphasic system.

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Conclusions

Hemicellulose prehydrolysate was converted to succinic acid in a biphasic system using toluene as the organic solvent. The rate limiting step in this process, furfural production and separation was optimized by determining ideal acid concentration (2%) and a good organic solvent (toluene) for extraction. The dilute sulfuric acid slows down the unwanted side reactions like furfural polymerization and toluene separates the furfural simultaneously. Oxidation of furfural in toluene was done using hydrogen peroxide (4:1 H2O2/ furfural mole ratio) and a heterogeneous acid catalyst, Amberlyst 15 (50 mg/ mmol furfural). The average molar yield of succinic acid obtained from furfural was found to be 52.34% in 24 h. The biphasic system used in this study facilitates simultaneous production, separation and oxidation of furfural to produce succinic acid. An advantage with the insolubility of succinic acid in toluene is that it helps easy separation after the reaction. We have also found that Amberlyst 15 can be recycled 3 times under the reported reaction conditions. This study shows the potential for the utilization of low value hemicellulose prehydrolysate to produce high value succinic acid. Acknowledgements We thank GreenField specialty alcohols Inc. for providing the substrate, wood hemicellulose prehydrolysate for this study. We are also thankful to the financial support provided by the Canadian government through the research grants from the Canada Foundation for Innovation (CFI) and Canada Research Chair program (CRC). References 1. Werpy, T.; Peterson, G. Top value added chemicals from biomass; Energy Efficiency and Renewable energy: US, 2004; pp 1-76. 2. Werpy, T.; Petersen, G.; Aden, A.; Bozell, J.; Holladay, J.; White, J.; Manheim, A.; Eliot, D.; Lasure, L.; Jones, S. Top value added chemicals from biomass. Volume 1-Results of screening for potential candidates from sugars and synthesis gas; DTIC Document: 2004. 3. Pinazo, J. M.; Domine, M. E.; Parvulescu, V.; Petru, F., Sustainability metrics for succinic acid production: A comparison between biomass-based and petrochemical routes. Catal. Today 2015, 239, 17-24. 4. Choudhary, H.; Nishimura, S.; Ebitani, K., Metal-free oxidative synthesis of succinic acid from biomass-derived furan compounds using a solid acid catalyst with hydrogen peroxide. Appl. Catal., A 2013, 458, 55-62.

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